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Distinctive Image Features from Scale-Invariant Keypoints David G. Lowe – IJCV 2004

Distinctive Image Features from Scale-Invariant Keypoints David G. Lowe – IJCV 2004. Brien Flewelling CPSC 643 Presentation 1. Overview. Introduction Motivation for this work Related Work Corners and other Local Features Invariant descriptors Similar Detection, Different Descriptor.

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Distinctive Image Features from Scale-Invariant Keypoints David G. Lowe – IJCV 2004

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  1. Distinctive Image Featuresfrom Scale-Invariant KeypointsDavid G. Lowe – IJCV 2004 Brien Flewelling CPSC 643 Presentation 1

  2. Overview • Introduction • Motivation for this work • Related Work • Corners and other Local Features • Invariant descriptors • Similar Detection, Different Descriptor

  3. Overview • Scalar Invariant Feature Transform • Scale Space Extrema Detection • Keypoint Localization • Orientation Assignment • Keypoint Descriptor • Experiments and Tests • Affine Changes, Large Data Bases, Object Recognition • Conclusions and Future Work

  4. Motivation …. Why SIFT anyway? • Highly Distinctive Features – Good Matching • Detailed Descriptor – High Uniqueness • Invariance to : • Scale – Zoom/Resampling • In plane Rotation • Partial Invariance to : • Lighting Change • Out of plane Rotation

  5. Related Work - Corner Detectors • Moravec (1981) – Stereo Matching using Corners • Harris and Stevens (1988) – Repeatability Improvements • Harris Corner Detector (1992) – commonly used in Structure from motion Solutions • “Large Gradients at a pre-determined scale”

  6. Related Work - Feature Matching • Zhang and Torr (1995) – Use of correlation, least squares and geometric constraints to match Harris corners over large image ranges and motions. • Schmidt and Mohr (1997) – Use of a rotationally invariant feature descriptor for matching images in large databases with Harris corners. • Lowe (1999) – Extension of feature descriptors to achieve scale invariance.

  7. Related Work – Stability to Changes • Crowley and Parker (1984) – Scale Space Peaks and matching of Tree Structures. • Lindberg (1993-94) – Scale Selection for good feature detection performance. • (Baumberg, 2000; Tuytelaars and Van Gool, 2000; Mikolajczyk and Schmid, 2002; Schaffalitzky and Zisserman, 2002; Brown and Lowe, 2002). – Affine Covariant Features

  8. Related Work – Other Features • Nelson and Selinger (1998) – Image Contours • Matas et al., (2002) – Maximally Stable Extremal Regions • Carneiro and Jepson (2002) – Phase Based Local Features • Schiele and Crowley (2000) – Multidimensional Histogram Descriptors

  9. SIFT – Scale Space Extrema Detection • Scale Space – A 1-parameter function of the image data • Gaussian Scale Space - Convolution with a Gaussian Kernel … No False Structure! • L(x, y, σ ) = G(x, y, σ) ∗ I(x, y) • G(x, y, σ ) = (1/2πσ2)*exp(-(x2+y2)/(2σ2)) • Detection of Extrema D(x, y, σ ) = (G(x, y, kσ) − G(x, y, σ)) ∗ I(x, y) = L(x, y, kσ) − L(x, y, σ ).

  10. The Difference of Gaussian Space • For constant scaling of σ this approximates the Laplacian of Gaussian • Approximating the derivative of the Gaussian function with respect to sigma we can obtain

  11. SIFT – Scale Space Extrema Detection • Construct the DOG scale space • K – factor of separation • S – number of • S+3 images in the stack for each octave • Resample and repeat • For each location compare to its 26 nearest neighbors in scale space retain only minima and maxima

  12. SIFT – Local Extrema Detection • Sampling of scale space is a balance between density of samples and the arbitrary feature frequencies • Test the reliability of matches over matching tasks vs. sampling frequencies • The most stable and useful frequencies can be detected with coarse sampling in scale.

  13. SIFT – Local Extrema Detection • Once a Scale Space Extrema is localized: • Calculate an interpolated fit for location, scale and ratio of principle curvatures • Compute a local Taylor Series Expansion of the DOG function. Find the Zero crossing of the derivative of this function:

  14. Evaluating Edge Responses by Comparing Principle Curvatures • The DOG space will have a large response to edges. • Poorly defined extrema have strong principle curvature along the edge but a weak principle curvature normal to it. • We may examine the relationship between principle curvatures by looking at the eigenvalues of the approximated Hessian matrix.

  15. The Hessian Matrix and Keypoint Rejection • The Hessian Matrix is approximated using Neighbor Differences • The ratio of the square of the trace to the determinant has a special relationship to the eigenvalue ratio

  16. SIFT – Orientation Assignment • To achieve rotational invariance, the local gradient orientations are examined to define a principle direction. • A magnitude weighted orientation histogram is calculated using the DOG image of nearest scale.

  17. SIFT – Keypoint Descriptor • The keypoint descriptor structures the local image information in the DOG image of nearest scale with respect to the assigned orientation. • Inspired by work by Edelman, Intrator, and Poggio (1997), the feature descriptor lists the gradient orientations in a structured vector

  18. SIFT – Keypoint Descriptor • The number of elements in the descriptor vector is calculated by the product of the number of histogram bins and the number of orientation directions typically 4x4x8 = 128

  19. Experiments – Affine Change • The SIFT descriptor was tested against a database of 40,000 keypoints. • The percent repeatability of correct matches vs. affine performs better than 50% for up to 50 degree rotations out of plane

  20. Experiments - Large Databases

  21. Experiments – Object Recognition • The Process: • Match Keypoints • Evaluate the Euclidian Distance between Candidate Matches. Retain the minimum if the next best match is not within a threshold standoff distance.

  22. Experiments – Object Recognition • When searching for the best match a prioritized Best Bin First search is used. • For purposes of object recognition a Hough Transform is used to cluster objects in pose space • Large Error Bounds, does not account well for affine variations – 4 DOF vs. 6 DOF

  23. Affine Solution • When a cluster of matches in pose space is identified it is verified geometrically by least squares:

  24. Results

  25. Conclusions • The SIFT algorithm has strength in its detailed descriptor and makes it robust to many transformations • Matching performs with reasonable repeatability for high clutter, occlusion, changes in scale, rotation, and illumination • This method works well for object recognition and the analysis of planar patches but struggles with 3d object geometry

  26. Future Work • Color SIFT • Object Classes base on SIFT Feature Distributions • SIFT based High Dynamic Range imagery • Project to come stay tuned

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